CN111519026A

CN111519026A - Method for leaching secondary coated gold hematite

Info

Publication number: CN111519026A
Application number: CN202010364724.XA
Authority: CN
Inventors: 党晓娥; 刘安全; 李林波; 刘佰龙
Original assignee: Xian University of Architecture and Technology
Current assignee: Xian University of Architecture and Technology
Priority date: 2020-04-30
Filing date: 2020-04-30
Publication date: 2020-08-11
Anticipated expiration: 2040-04-30
Also published as: CN111519026B

Abstract

The invention discloses a method for leaching secondary coated gold hematite, which comprises the steps of firstly mixing a secondary coated gold ore sample containing hematite with water to obtain mixed ore pulp; adding an oxalic acid and oxalate mixed reagent into the mixed ore pulp, and continuously stirring in the adding process to obtain leached ore pulp; stirring and leaching the leached ore pulp, and filtering and separating to obtain leaching slag and leaching liquid; leaching slag is iron-removing slag; the invention provides a method for leaching secondary coated gold hematite, which comprises the steps of adding a mixed solution of oxalic acid and oxalate into a secondary coated gold sample containing hematite, and utilizing C₂O₄ ^2‑For Fe³⁺Has strong complexation to generate Fe (C) with large accumulative stability constant₂O₄)₃ ^3‑The method has the advantages of high iron leaching speed, high iron leaching rate (up to more than 95%), low energy consumption in the leaching process, simple iron removal process equipment, small environmental pollution and easy industrialization.

Description

Method for leaching secondary coated gold hematite

Technical Field

The invention relates to the technical field of iron removal by pretreatment of hematite coated refractory gold ore resources, in particular to a method for leaching secondary coated gold hematite.

Background

At present, a large amount of industrial waste residues containing hematite and gold mainly comprise roasting cyanidation tailings produced by the gold smelting industry and sulfuric acid cinder produced by the synthetic sulfuric acid industry. The gold industry differs from other metal production in that the tailings yield is close to 100%, while the synthetic sulfuric acid industry produces about 0.8% of sulfuric acid cinder per 1t of sulfuric acid produced. According to statistics, the annual discharge of cyanidation tailings of gold smelting enterprises in China is about 2450 million tons, and the annual discharge of sulfuric acid cinder in the synthetic sulfuric acid industry exceeds 1000 million tons.

Because of the geochemical properties of gold, which is iron-philic and sulfur-philic, gold-bearing ores generally contain pyrite and arsenopyrite, with a large portion of the gold being encapsulated by both. In recent years, along with the increasing exhaustion of the traditional high-quality easily-treated gold ore resources, the difficultly-treated gold ore becomes the main raw material for gold production, the direct cyaniding gold leaching effect of the difficultly-treated gold ore is poor, and the roasting pretreatment is generally carried out on the gold in the industry for recovering the gold: if the high arsenic gold concentrate and the copper-containing gold concentrate are respectively subjected to secondary roasting and sulfating roasting to obtain secondary gold calcine and primary gold calcine, the secondary gold calcine is washed by water to remove sulfate and then cyanided for gold leaching, the primary gold calcine is subjected to sulfuric acid copper removal and then cyanided for gold leaching, and gold leaching residues are secondary roasting cyanided tailings and primary roasting cyanided tailings (the secondary roasting cyanided tailings and the primary roasting cyanided tailings are collectively called roasting cyanided tailings); the synthetic sulfuric acid industry carries out fluidized roasting treatment and desulfurization on high-grade pyrite, and SO in flue gas is utilized₂To prepare the sulfuric acid, and the roasting residue is the sulfuric acid roasting residue. Because of the melting and secondary crystallization of iron phase in the roasting process, part of gold is wrapped by the compact hematite, the roasting cyaniding tailings and sulfuric acid roasting residues generally have low cyaniding gold leaching rate and overhigh gold content, the gold grade of the roasting cyaniding tailings is generally 1-8 g/t, and the gold grade of part of the secondary roasting cyaniding tailings is as high as more than 10 g/t. The roasting cyanidation tailings contain 25-35% of iron and 30-80 g/silver besides gold, and are important secondary resources; the iron content of the sulfuric acid cinder is about 30 to 50 percent. In addition, the copper-containing slag also contains a certain amount of gold, silver and other elements, so that the sulfuric acid cinder is also an important gold-containing secondary resourceA source. At present, no effective large-scale method is available for treating the industrial waste residues containing gold and hematite, so most of the waste residues are piled in the open air. Therefore, it is urgent to recover gold from such slag and to utilize the high iron content thereof.

A large number of studies show that the destruction of hematite wrapping gold is the most effective way to improve the gold leaching rate in the slag. At present, the methods for removing hematite from the slag mainly comprise sulfuric acid leaching, hydrochloric acid leaching, copper powder reduction strengthening sulfuric acid leaching, sulfuric acid curing-water leaching, high-temperature reduction-sulfuric acid leaching, magnetizing roasting-magnetic separation for gold and iron, magnetizing roasting-cyaniding gold leaching, direct chlorination roasting, chlorination reduction roasting, melt chlorination and the like. The inorganic acid method has high acid consumption in the iron leaching process, poor working environment, poor leaching selectivity and complex leaching solution components, so that the treatment process is complex; the iron ore concentrate obtained by magnetizing and roasting has low grade, and the gold and the iron are difficult to effectively separate; although gold and other valuable elements in the tailings can be effectively recovered by chloridizing roasting, the chloridizing temperature is up to 1100 ℃, a matched flue gas treatment system is required, the process flow is long, and the production investment is large. Most of the current methods are not applied industrially on a large scale or are not applied due to their own limitations or also handling the laboratory research stage. Therefore, how to efficiently and economically remove the iron in the slag and expose the gold wrapped by the hematite and how to develop a new clean technology for improving the gold recovery rate is important.

Disclosure of Invention

Aiming at the technical problems in the prior art, the invention provides a method for leaching a secondary coated gold hematite, which aims to solve the technical problems in the prior art that the iron removal effect of a mineral sample containing hematite secondary coated gold is poor, the energy consumption is high, the process flow is complex and the like.

In order to achieve the purpose, the invention adopts the technical scheme that:

the invention provides a method for leaching secondary coated hematite, which comprises the following steps:

step 1, mixing a secondary coated gold ore sample containing hematite with water to obtain mixed ore pulp;

step 2, adding a mixed reagent of oxalic acid and oxalate into the mixed ore pulp, and continuously stirring in the adding process to obtain leached ore pulp;

and 3, stirring and leaching the leached ore pulp, and filtering and separating to obtain leached slag and a leaching solution, wherein the leached slag is the iron-removing slag.

Further, the method also comprises a step 4 of recovering gold and silver by adopting iron removal slag.

Further, in step 1, the secondary coated gold sample containing hematite is one of gold calcine, roasted cyanidation tailings and sulfuric acid cinder.

Further, in the step 1, in the mixed ore pulp, the liquid-solid ratio of the secondary coated gold ore sample containing hematite to water is (4-6) mL/1 g.

Further, in the step 2, the molar mass ratio of the oxalic acid to the oxalate in the mixed reagent of the oxalic acid and the oxalate is (0.98-1.05): (0.98-1.05); wherein the oxalate is K₂C₂O₄Or (NH)₄)₂C₂O₄，C₂O₄ ^2-The molar mass of the iron-containing iron ore is 3.5 to 5.2 times of the total iron molar mass in the gold ore sample coated with hematite for the second time.

Further, in the step 3, in the agitation leaching process, the leaching temperature is 80-95 ℃, the agitation leaching time is 60-90min, and the agitation speed is 400-600/min.

Further, in the step 4, gold leaching is carried out on the iron removal residues by adopting a cyanide method or a non-cyanide method, gold and silver are recovered, the gold leaching residues are used as a slagging solvent to recover residual gold and silver in the pyrometallurgical copper-lead smelting process, and quartz in the residues is comprehensively utilized.

Further, in the step 4, the iron-removing slag is directly used as a slagging solvent in the copper pyrometallurgy process, gold and silver are recovered in the pyrometallurgy process, and quartz in the copper and lead is comprehensively utilized.

Compared with the prior art, the invention has the beneficial effects that:

the invention provides a method for leaching secondary coated gold hematite, which comprises the steps of adding a mixed solution of oxalic acid and oxalate into a secondary coated gold ore sample containing hematite, and utilizing C₂O₄ ^2-For Fe³⁺Has strong complexation to generate Fe (C) with large accumulative stability constant₂O₄)₃ ^3-The method has the advantages of high iron leaching speed, high iron leaching rate (up to more than 95%), low energy consumption in the leaching process, simple iron removal process equipment, small environmental pollution and easy industrialization.

Further, after iron is removed from the secondary coated gold ore sample containing hematite, gold, silver and silicon are left in the iron-removing slag, so that the hematite coated gold is exposed; because the hematite is removed, noble metals gold and silver in the iron-removing slag are effectively enriched, the iron-removing slag can be used for gold leaching by a cyanidation method or non-cyanidation method, the obtained gold leaching residue mainly comprises quartz, and a small amount of gold and residual silver wrapped by the quartz, so the gold leaching residue can be used as a slagging solvent to recover the residual gold and silver in the pyrometallurgical copper-lead smelting process, and the quartz in the residue is comprehensively utilized; or the iron removal slag is directly used as a slagging solvent without wet gold leaching, gold and silver are recovered in the pyrometallurgical copper-lead smelting process, and quartz is comprehensively utilized.

Further, the invention aims to remove hematite coated with gold, the bare hematite is coated with gold, and hematite coated with gold is mainly formed by oxidizing pyrite and arsenopyrite at high temperature, so the iron removal method is not only suitable for removing the hematite in roasting cyanidation tailings, but also suitable for removing the hematite in second-stage gold calcine, first-stage gold calcine copper sulfate leaching slag and sulfuric acid roasting slag.

Further, the liquid-solid ratio is controlled to be (4-6) mL/1g, in the liquid-solid ratio range, the influence of the change of the water volume on the leaching pH value is small, and the pH value of the leaching system is mainly adjusted by adjusting H₂C₂O₄And K₂C₂O₄Or is going to H₂C₂O₄And (NH)₄)₂C₂O₄Is carried out in a molar ratio of (a).

Furthermore, the leaching agent is a mixed leaching agent, and K is contained in the mixed leaching agent₂C₂O₄Or (NH)₄)₂C₂O₄In the course of leachingTwo functions are realized: first, complex Fe is provided³⁺C of (A)₂O₄ ^2-Ions; secondly, adjusting the pH value of a leaching system; because of Fe³⁺And C₂O₄ ^2-Can form Fe (C)₂O₄)⁺、Fe(C₂O₄)₂ ^-And Fe (C)₂O₄)₃ ^3-Three complex ions with different cumulative stability constants, wherein Fe (C)₂O₄)₃ ^3-The cumulative stability constant of (a) is maximum. Hematite leached Fe³⁺Which iron oxalate complex is present in the leach solution depends on the pH of the leaching system; fe leached from hematite in the present invention³⁺Fe (C) with a relatively large cumulative stability constant₂O₄)₃ ^3-Fe leached from hematite³⁺With Fe (C) only₂O₄)₃ ^3-The form of the iron-containing composite material exists in the leaching liquid stably, and the leaching rate of iron can reach more than 95%.

Further, 1 mole of Fe was produced by leaching in hematite³⁺Complete formation of Fe (C) in the leach solution₂O₄)₃ ^3-Theoretically at least 3 moles of C are required₂O₄ ^2-I.e. at least satisfy C₂O₄ ^2-/Fe³⁺The molar mass ratio is 3: 1; leaching agent C₂O₄ ^2-The larger the molar mass, the C in the leachate₂O₄ ^2-The higher the concentration is, the higher the leaching driving force of the hematite is, and the better the leaching effect is; and excess free C₂O₄ ^2-The existence of the Fe can ensure the Fe in the leaching solution³⁺Completely with Fe (C)₂O₄)₃ ^3-In the form of Fe (C)₂O₄)₃ ^3-The stable existing pH value range is widened, so that the pH value in the leaching process is easier to control; meanwhile, the gold-containing ore sample contains a small amount of gangue components such as CaO and MgO, which are Ca leached in the leaching process²⁺And Mg²⁺Part C will also be consumed₂O₄ ^2-Formation of CaC₂O₄And MgC₂O₄Into the iron-removing slag, so that the leaching agent C₂O₄ ^2-The molar mass is generally greater than C₂O₄ ^2-3 times the theoretical molar mass, so C₂O₄ ^2-The molar mass of the iron is 3.5 to 5.2 times of the total iron molar mass in the gold mineral coated with hematite, so that the leaching effect of the iron is effectively improved.

The invention relates to a method for leaching hematite with secondary coated gold, which adopts a mixed reagent of oxalic acid and oxalate to rapidly leach hematite in roasted cyanidation tailings, gold calcine or sulfuric acid calcine, wherein leached iron removal residues can be used for gold leaching by a cyanidation method or non-cyanidation method to obtain gold leaching residues, the main components in the gold leaching residues are quartz, a small amount of gold coated by the quartz and un-leached silver, and the gold leaching residues can be used as a slagging solvent in a pyrometallurgical copper smelting process; the iron-removing slag can be directly used as a slagging solvent without wet gold leaching, gold and silver in the iron-removing slag are recycled in the pyrometallurgical copper-lead smelting process, and quartz is comprehensively utilized.

Detailed Description

In order to make the technical problems, technical solutions and advantageous effects solved by the present invention more apparent, the following embodiments further describe the present invention in detail. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

step 1, mixing a secondary coated gold ore sample containing hematite and water according to a liquid-solid ratio of (4-6): 1, and stirring to obtain mixed ore pulp; wherein, the secondary coating gold ore sample containing hematite adopts one of gold calcine, roasting cyanidation tailings and sulfuric acid cinder;

step 2, adding an oxalic acid and oxalate mixed reagent into the mixed ore pulp, and continuously stirring in the adding process to obtain leached ore pulp, wherein the oxalic acid and the oxalate in the oxalic acid and oxalate mixed reagent are mixed according to the molar mass ratio of (0.98-1.05) to (0.98-1.05); wherein oxalate adopts K₂C₂O₄Or (NH)₄)₂C₂O₄，C₂O₄ ^2-The molar mass of the iron is 3.5 to 5.2 times of the total iron molar mass in the secondary coating gold ore sample containing hematite;

step 3, stirring and leaching the leached ore pulp for 60-90min at the temperature of 80-95 ℃, and filtering and separating to obtain leaching residues and leaching liquid; leaching slag is iron-removing slag, and leaching liquid is ferric oxalate complex leaching liquid;

step 4, recovering gold and silver from the iron removal slag, specifically, leaching gold from the iron removal slag by adopting a cyanide method or a non-cyanide method to obtain gold leaching residue, wherein the gold leaching residue can be used as a slagging solvent to recover residual gold and silver in a pyrometallurgical copper-lead smelting process, and quartz in the residue is comprehensively utilized; or the iron-removing slag is directly used as a slagging solvent without being leached with gold, gold and silver are recovered in the pyrometallurgical copper-lead smelting process, and quartz in the iron-removing slag is comprehensively utilized.

The method for leaching the secondary coated gold hematite provided by the invention comprises the steps of adding an oxalic acid and oxalate mixed reagent into mixed ore pulp, and utilizing C₂O₄ ^2-For Fe³⁺Strong complexation to Fe (C)₂O₄)₃ ^3-The hematite containing the hematite and secondarily wrapping the gold ore sample is leached in a complexing way, the iron leaching speed is high, the iron leaching rate is high, and the iron leaching rate is up to more than 95 percent; the leaching process has low energy consumption, simple iron removal equipment and little environmental pollution, and is easy to industrialize.

Example 1

The method for leaching the secondary coated gold hematite is used for removing iron from certain two-stage roasting and cyaniding tailings, wherein the gold content in the two-stage roasting and cyaniding tailings reaches up to 13.03g/t, and the iron content is 30.60 percent, and the method specifically comprises the following steps:

step 1, taking 200g of the secondary calcine cyanidation tailing slag, and adding the secondary calcine cyanidation tailing slag and water into a leaching tank according to the liquid-solid ratio of 4mL/1g to obtain mixed ore pulp;

step 2, adding solid oxalic acid and potassium oxalate into the leaching tank in the step 1 according to the molar mass ratio of 1:1Performing the following steps; stirring the mixture during the process of adding oxalic acid and oxalate to obtain leached ore pulp; wherein C in the leached ore pulp₂O₄ ^2-The molar mass of the iron is 3.9 times of the total iron molar mass in the secondary calcine cyanidation tailing slag;

step 3, stirring and leaching the leached ore pulp at 95 ℃ for 60min, and then filtering and separating to obtain leaching slag and leaching liquid, wherein the leaching slag is the iron-removing slag, and the stirring speed in the leaching process is 400 r/min;

step 4, recovering gold and silver from the iron removal slag, specifically, leaching gold from the iron removal slag by adopting a cyanidation method or a non-cyanidation method to obtain gold leaching residue, recovering the residual gold and silver in a pyrometallurgical copper-lead smelting process by taking the gold leaching residue as a slagging solvent, and comprehensively utilizing quartz in the gold leaching residue; or the iron-removing slag is directly used as a slagging solvent without being leached with gold, gold and silver are recovered in the pyrometallurgical copper-lead smelting process, and quartz in the iron-removing slag is comprehensively utilized.

The results of the weighing analysis of the iron-removing slag in the embodiment after cleaning and drying show that: the weight loss rate of the two-stage calcine cyanidation tailing slag is 50.02 percent, the iron content in the iron-removed slag is 1.99 percent, and the iron removal rate is as high as 96.30 percent; the iron removing slag is cyanided to extract gold, and the gold extraction rate is improved by 52.4 percent compared with that before iron removal.

Example 2

The method for leaching the secondary coated gold hematite is used for removing iron from certain roasting cyanidation tailings, wherein the gold content in the roasting cyanidation tailings is 4g/t, and the iron content is 38.00 percent, and the method specifically comprises the following steps:

step 1, weighing 200g of the roasting cyanidation tailings, and adding the roasting cyanidation tailings and water into a leaching tank according to the liquid-solid ratio of 6mL/1 g;

step 2, adding solid oxalic acid and ammonium oxalate into the leaching tank in the step 1 according to the molar mass ratio of 0.98:1.05, stirring in the process of adding oxalic acid and ammonium oxalate to obtain leached ore pulp, wherein C in the leached ore pulp₂O₄ ^2-The molar mass of the iron is 4.02 times of the total molar mass of the iron in the roasting cyanidation tailings;

step 3, stirring and leaching the leached ore pulp at 90 ℃ for 60min, and filtering and separating to obtain leaching residues and leaching liquid; leaching slag is the iron-removing slag, the leaching solution is the ferric oxalate complex leaching solution, and the stirring speed in the leaching process is 500 r/min;

step 4, recovering gold and silver from the iron removal slag, specifically, leaching gold from the iron removal slag by adopting a cyanidation method or a non-cyanidation method to obtain gold leaching residue, recovering residual gold and silver in a pyrometallurgical copper-lead smelting process by taking the gold leaching residue as a slagging solvent, and comprehensively utilizing quartz in the gold leaching residue; or the iron-removing slag is directly used as a slagging solvent without being leached with gold, gold and silver are recovered in the pyrometallurgical copper-lead smelting process, and quartz in the iron-removing slag is comprehensively utilized.

The results of the weighing analysis of the iron-removing slag in the embodiment after cleaning and drying show that: the weight loss rate of the calcine cyanidation tailing slag is 64.35 percent, the iron content in the iron-removed slag is 1.45 percent, and the iron removal rate is as high as 98.64 percent; the iron-removing slag is cyanided to leach gold, the gold content in the slag is 0.74g/t, and the gold leaching rate is improved by 98.64 percent compared with that before iron removal.

Example 3

The method for leaching the secondary coated gold hematite is used for removing iron from certain sulfuric acid cinder, wherein the contents of gold, silver, copper, lead, zinc and iron in the cinder are respectively 4g/t, 110g/t, 0.6%, 1.0%, 2.2% and 57%, and the method specifically comprises the following steps:

step 1, taking 30g of the sulfuric acid cinder, and adding the sulfuric acid cinder and water into a leaching tank according to the liquid-solid ratio of 6mL/1 g;

step 2, adding solid oxalic acid and ammonium oxalate into the leaching tank in the step 1 according to the molar mass ratio of 1:1, adding oxalic acid and ammonium oxalate, stirring to obtain leached ore pulp, wherein C in the leached ore pulp₂O₄ ^2-The molar mass of the iron is 5.2 times of the total molar mass of the iron in the sulfuric acid cinder;

step 3, stirring and leaching the leached ore pulp at 80 ℃, filtering and separating after leaching for 90min to obtain leaching slag and leaching liquid, wherein the leaching slag is the iron-removing slag, the leaching liquid is the ferric oxalate complex leaching liquid, and the stirring speed in the leaching process is 400 r/min;

step 4, recovering gold and silver from the iron-removing slag, specifically, leaching gold from the iron-removing slag by adopting a cyaniding method or a non-cyaniding method to obtain gold leaching residue, recovering residual gold and silver from the gold leaching residue as a slagging solvent in a pyrometallurgical copper-lead smelting process, and comprehensively utilizing quartz in the gold leaching residue; or the iron removal slag is directly used as a slagging solvent without wet gold leaching, gold and silver are recovered in the pyrometallurgical copper-lead smelting process, and quartz in the copper-lead smelting process is comprehensively utilized.

The results of the weighing analysis of the iron-removing slag in the embodiment after cleaning and drying show that: the weight loss of the sulfuric acid cinder is 75.4 percent, the iron content in the iron-removed slag is 1.40 percent, and the iron-removing rate is as high as 99.40 percent.

Example 4

The method for leaching the secondary coated gold hematite is used for removing iron from certain secondary calcine cyanidation tailings, wherein the iron content in the secondary calcine cyanidation tailings is 32.60 percent, and the method specifically comprises the following steps:

step 1, mixing 571g of the secondary calcine cyanidation tailings with water according to the liquid-solid ratio of 4mL/1g, and stirring to obtain mixed ore pulp;

step 2, adding solid oxalic acid and ammonium oxalate into the leaching tank in the step 1 according to the molar mass ratio of 0.98:1, stirring in the process of adding oxalic acid and ammonium oxalate to obtain leached ore pulp, wherein C in the leached ore pulp₂O₄ ^2-The molar mass of the iron is 4.2 times of the total iron molar mass in the secondary calcine cyanidation tailings;

step 3, stirring and leaching the leached ore pulp at 90 ℃ for 60min, and filtering and separating to obtain leaching residues and leaching liquid; leaching slag is iron-removing slag, and leaching liquid is ferric oxalate complex leaching liquid; wherein the stirring speed is 600 r/min;

step 4, recovering gold and silver from the iron removal slag, specifically, leaching gold from the iron removal slag by adopting a cyanidation method or a non-cyanidation method to obtain gold leaching residue, recovering residual gold and silver in a pyrometallurgical copper-lead smelting process by taking the gold leaching residue as a slagging solvent, and comprehensively utilizing quartz in the gold leaching residue; or the iron removal slag is directly used as a slagging solvent without wet gold leaching, gold and silver are recovered in the pyrometallurgical copper-lead smelting process, and quartz in the copper-lead smelting process is comprehensively utilized.

The results of the weighing analysis of the iron-removing slag in the embodiment after cleaning and drying show that: the weight loss rate of the two-stage calcine cyanidation tailings is 53.65%, the iron content in the iron-removed slag is 3.26%, and the iron removal rate is up to 95.36%.

Example 5

The method for leaching the secondary coated gold hematite is used for removing iron from certain second-stage calcine cyanidation tailings, wherein the iron content in the certain second-stage calcine cyanidation tailings is 30.10 percent, and the method specifically comprises the following steps:

step 1, taking 200g of the secondary calcine cyanidation tailings, mixing the secondary calcine cyanidation tailings with water according to the liquid-solid ratio of 4mL/1g, and stirring to obtain mixed ore pulp;

step 2, adding solid oxalic acid and ammonium oxalate into the leaching tank in the step 1 according to the molar mass ratio of 0.99:1.05, stirring in the process of adding oxalic acid and ammonium oxalate to obtain leached ore pulp, wherein C in the leached ore pulp₂O₄ ^2-The molar mass of the iron is 3.5 times of the total molar mass of the iron in the secondary calcine cyanidation tailings;

step 3, stirring and leaching the leached ore pulp at 90 ℃ for 65min, and filtering and separating to obtain leaching residues and leaching liquid; leaching slag is the iron-removing slag, the leaching solution is the ferric oxalate complex leaching solution, and the stirring speed in the leaching process is 400 r/min;

step 4, recovering gold and silver from the iron removal slag, specifically, leaching gold from the iron removal slag by adopting a cyanidation method or a non-cyanidation method to obtain gold leaching residue, recovering residual gold and silver from the gold leaching residue as a slagging solvent in a pyrometallurgical copper-lead smelting process, and comprehensively utilizing quartz in the gold leaching residue; or the iron removal slag is directly used as a slagging solvent without wet gold leaching, gold and silver are recovered in the pyrometallurgical copper-lead smelting process, and quartz in the copper-lead smelting process is comprehensively utilized.

The results of the weighing analysis of the iron-removing slag in the embodiment after cleaning and drying show that: the weight loss rate of the two-stage calcine cyanidation tailings is 50 percent, the iron content in the iron-removed slag is 1.99 percent, and the iron removal rate is up to 96.63 percent.

Example 6

The method for leaching the secondary coated gold hematite is used for removing iron from a certain second section of gold calcine, wherein the gold content in the second section of gold calcine is 57.50g/t, and the hematite content is 25.12%. The method specifically comprises the following steps:

step 1, taking 20g of the second-stage gold calcine, mixing the second-stage gold calcine with water according to the liquid-solid ratio of 5mL/1g, and stirring to obtain mixed ore pulp;

step 2, adding solid oxalic acid and ammonium oxalate into the leaching tank in the step 1 according to the molar mass ratio of 1:1, and stirring in the process of adding oxalic acid and ammonium oxalate to obtain leached ore pulp; wherein C in the leached ore pulp₂O₄ ^2-The molar mass of the second-stage gold calcine is 3.5 times of the total molar mass of iron in the second-stage gold calcine;

step 3, stirring and leaching the leached ore pulp at 90 ℃ for 60min, and filtering and separating to obtain leaching residues and leaching liquid; leaching slag is iron-removing slag, and leaching liquid is ferric oxalate complex leaching liquid; wherein the stirring speed is 400 r/min;

The results of the weighing analysis of the iron-removing slag in the embodiment after cleaning and drying show that: the weight loss rate of the second-stage gold calcine is 49.2 percent, the iron content in the iron-removed slag is 2.40 percent, and the iron-removing rate is up to 95.03 percent.

The method for leaching the secondary coated gold hematite is not only suitable for pre-treating the roasted cyanidation tailings to remove the hematite, but also suitable for pre-treating the gold roasted before cyanidation leaching to remove the hematite or using the sulfuric acid cinder to remove the hematite, so that the gold coated by the hematite is exposed, and the recovery rate of the gold in the gold ore sample containing the hematite is improved; according to the invention, the mixed reagent of oxalic acid and oxalate is adopted to leach iron, the leaching speed is high, the leaching rate of iron is as high as more than 95%, the energy consumption in the leaching process is low, the iron removal equipment is simple, the comprehensive treatment process flow of iron removal slag and leachate is simple, the leachate can recover iron, regenerated oxalic acid and oxalate, the recycling of system water can be realized, and the industrialization is easy to realize.

The above description is only illustrative of the preferred embodiments of the present invention, and any structural changes, improvements, modifications, etc. made without departing from the principle of the present invention are deemed to be within the scope of the present invention.

Claims

1. A method for leaching secondary coated hematite is characterized by comprising the following steps:

2. The method for leaching twice-coated aurite ore according to claim 1, further comprising a step 4 of recovering gold and silver from the iron-removed slag.

3. The method for leaching secondary coated gold hematite according to claim 1, wherein in step 1, the secondary coated gold sample containing hematite is one of gold calcine, roasted cyanidation tailings and sulfuric acid calcine.

4. The method for leaching the secondary coated aurite ore according to the claim 1, wherein in the step 1, the liquid-solid ratio of the secondary coated aurite sample containing the hematite and water in the mixed ore pulp is (4-6) mL/1 g.

5. The method for leaching hematite coated with secondary gold ore as claimed in claim 1, wherein the oxalic acid and oxalate mixed reagent in step 2 is oxalic acid and oxalateThe molar mass ratio is (0.98-1.05): (0.98-1.05); wherein the oxalate is K₂C₂O₄Or (NH)₄)₂C₂O₄，C₂O₄ ^2-The molar mass of the iron-containing iron ore is 3.5 to 5.2 times of the total iron molar mass in the gold ore sample coated with hematite for the second time.

6. The method for leaching secondary coated aurite ore as claimed in claim 1, wherein in the step 3, the agitation leaching process is performed, the leaching temperature is 80-95 ℃, the agitation leaching time is 60-90min, and the agitation speed is 400-600/min.

7. The method for leaching the secondary coated gold hematite as claimed in claim 2, wherein in the step 4, gold leaching is performed on the iron removal slag by a cyanidation method or a non-cyanidation method, gold and silver are recovered, and the gold leaching residue is used as a slagging solvent to recover the residual gold and silver in the pyrometallurgical copper-lead smelting process and comprehensively utilize quartz therein.

8. The method for leaching the secondary coated gold hematite as claimed in claim 2, wherein in step 4, the iron-removed slag is directly used as a slagging solvent in the pyrometallurgical process of copper and lead, gold and silver are recovered in the pyrometallurgical process of copper and lead, and quartz in the copper and lead is comprehensively utilized.